#include "cache.h" #include "tag.h" #include "commit.h" #include "tree.h" #include "blob.h" #include "tree-walk.h" #include "refs.h" #include "remote.h" static int get_sha1_oneline(const char *, unsigned char *, struct commit_list *); typedef int (*disambiguate_hint_fn)(const unsigned char *, void *); struct disambiguate_state { disambiguate_hint_fn fn; void *cb_data; unsigned char candidate[20]; unsigned candidate_exists:1; unsigned candidate_checked:1; unsigned candidate_ok:1; unsigned disambiguate_fn_used:1; unsigned ambiguous:1; unsigned always_call_fn:1; }; static void update_candidates(struct disambiguate_state *ds, const unsigned char *current) { if (ds->always_call_fn) { ds->ambiguous = ds->fn(current, ds->cb_data) ? 1 : 0; return; } if (!ds->candidate_exists) { /* this is the first candidate */ hashcpy(ds->candidate, current); ds->candidate_exists = 1; return; } else if (!hashcmp(ds->candidate, current)) { /* the same as what we already have seen */ return; } if (!ds->fn) { /* cannot disambiguate between ds->candidate and current */ ds->ambiguous = 1; return; } if (!ds->candidate_checked) { ds->candidate_ok = ds->fn(ds->candidate, ds->cb_data); ds->disambiguate_fn_used = 1; ds->candidate_checked = 1; } if (!ds->candidate_ok) { /* discard the candidate; we know it does not satisify fn */ hashcpy(ds->candidate, current); ds->candidate_checked = 0; return; } /* if we reach this point, we know ds->candidate satisfies fn */ if (ds->fn(current, ds->cb_data)) { /* * if both current and candidate satisfy fn, we cannot * disambiguate. */ ds->candidate_ok = 0; ds->ambiguous = 1; } /* otherwise, current can be discarded and candidate is still good */ } static void find_short_object_filename(int len, const char *hex_pfx, struct disambiguate_state *ds) { struct alternate_object_database *alt; char hex[40]; static struct alternate_object_database *fakeent; if (!fakeent) { /* * Create a "fake" alternate object database that * points to our own object database, to make it * easier to get a temporary working space in * alt->name/alt->base while iterating over the * object databases including our own. */ const char *objdir = get_object_directory(); int objdir_len = strlen(objdir); int entlen = objdir_len + 43; fakeent = xmalloc(sizeof(*fakeent) + entlen); memcpy(fakeent->base, objdir, objdir_len); fakeent->name = fakeent->base + objdir_len + 1; fakeent->name[-1] = '/'; } fakeent->next = alt_odb_list; sprintf(hex, "%.2s", hex_pfx); for (alt = fakeent; alt && !ds->ambiguous; alt = alt->next) { struct dirent *de; DIR *dir; sprintf(alt->name, "%.2s/", hex_pfx); dir = opendir(alt->base); if (!dir) continue; while (!ds->ambiguous && (de = readdir(dir)) != NULL) { unsigned char sha1[20]; if (strlen(de->d_name) != 38) continue; if (memcmp(de->d_name, hex_pfx + 2, len - 2)) continue; memcpy(hex + 2, de->d_name, 38); if (!get_sha1_hex(hex, sha1)) update_candidates(ds, sha1); } closedir(dir); } } static int match_sha(unsigned len, const unsigned char *a, const unsigned char *b) { do { if (*a != *b) return 0; a++; b++; len -= 2; } while (len > 1); if (len) if ((*a ^ *b) & 0xf0) return 0; return 1; } static void unique_in_pack(int len, const unsigned char *bin_pfx, struct packed_git *p, struct disambiguate_state *ds) { uint32_t num, last, i, first = 0; const unsigned char *current = NULL; open_pack_index(p); num = p->num_objects; last = num; while (first < last) { uint32_t mid = (first + last) / 2; const unsigned char *current; int cmp; current = nth_packed_object_sha1(p, mid); cmp = hashcmp(bin_pfx, current); if (!cmp) { first = mid; break; } if (cmp > 0) { first = mid+1; continue; } last = mid; } /* * At this point, "first" is the location of the lowest object * with an object name that could match "bin_pfx". See if we have * 0, 1 or more objects that actually match(es). */ for (i = first; i < num && !ds->ambiguous; i++) { current = nth_packed_object_sha1(p, i); if (!match_sha(len, bin_pfx, current)) break; update_candidates(ds, current); } } static void find_short_packed_object(int len, const unsigned char *bin_pfx, struct disambiguate_state *ds) { struct packed_git *p; prepare_packed_git(); for (p = packed_git; p && !ds->ambiguous; p = p->next) unique_in_pack(len, bin_pfx, p, ds); } #define SHORT_NAME_NOT_FOUND (-1) #define SHORT_NAME_AMBIGUOUS (-2) static int finish_object_disambiguation(struct disambiguate_state *ds, unsigned char *sha1) { if (ds->ambiguous) return SHORT_NAME_AMBIGUOUS; if (!ds->candidate_exists) return SHORT_NAME_NOT_FOUND; if (!ds->candidate_checked) /* * If this is the only candidate, there is no point * calling the disambiguation hint callback. * * On the other hand, if the current candidate * replaced an earlier candidate that did _not_ pass * the disambiguation hint callback, then we do have * more than one objects that match the short name * given, so we should make sure this one matches; * otherwise, if we discovered this one and the one * that we previously discarded in the reverse order, * we would end up showing different results in the * same repository! */ ds->candidate_ok = (!ds->disambiguate_fn_used || ds->fn(ds->candidate, ds->cb_data)); if (!ds->candidate_ok) return SHORT_NAME_AMBIGUOUS; hashcpy(sha1, ds->candidate); return 0; } static int disambiguate_commit_only(const unsigned char *sha1, void *cb_data_unused) { int kind = sha1_object_info(sha1, NULL); return kind == OBJ_COMMIT; } static int disambiguate_committish_only(const unsigned char *sha1, void *cb_data_unused) { struct object *obj; int kind; kind = sha1_object_info(sha1, NULL); if (kind == OBJ_COMMIT) return 1; if (kind != OBJ_TAG) return 0; /* We need to do this the hard way... */ obj = deref_tag(lookup_object(sha1), NULL, 0); if (obj && obj->type == OBJ_COMMIT) return 1; return 0; } static int disambiguate_tree_only(const unsigned char *sha1, void *cb_data_unused) { int kind = sha1_object_info(sha1, NULL); return kind == OBJ_TREE; } static int disambiguate_treeish_only(const unsigned char *sha1, void *cb_data_unused) { struct object *obj; int kind; kind = sha1_object_info(sha1, NULL); if (kind == OBJ_TREE || kind == OBJ_COMMIT) return 1; if (kind != OBJ_TAG) return 0; /* We need to do this the hard way... */ obj = deref_tag(lookup_object(sha1), NULL, 0); if (obj && (obj->type == OBJ_TREE || obj->type == OBJ_COMMIT)) return 1; return 0; } static int disambiguate_blob_only(const unsigned char *sha1, void *cb_data_unused) { int kind = sha1_object_info(sha1, NULL); return kind == OBJ_BLOB; } static int prepare_prefixes(const char *name, int len, unsigned char *bin_pfx, char *hex_pfx) { int i; hashclr(bin_pfx); memset(hex_pfx, 'x', 40); for (i = 0; i < len ;i++) { unsigned char c = name[i]; unsigned char val; if (c >= '0' && c <= '9') val = c - '0'; else if (c >= 'a' && c <= 'f') val = c - 'a' + 10; else if (c >= 'A' && c <='F') { val = c - 'A' + 10; c -= 'A' - 'a'; } else return -1; hex_pfx[i] = c; if (!(i & 1)) val <<= 4; bin_pfx[i >> 1] |= val; } return 0; } static int get_short_sha1(const char *name, int len, unsigned char *sha1, unsigned flags) { int status; char hex_pfx[40]; unsigned char bin_pfx[20]; struct disambiguate_state ds; int quietly = !!(flags & GET_SHA1_QUIETLY); if (len < MINIMUM_ABBREV || len > 40) return -1; if (prepare_prefixes(name, len, bin_pfx, hex_pfx) < 0) return -1; prepare_alt_odb(); memset(&ds, 0, sizeof(ds)); if (flags & GET_SHA1_COMMIT) ds.fn = disambiguate_commit_only; else if (flags & GET_SHA1_COMMITTISH) ds.fn = disambiguate_committish_only; else if (flags & GET_SHA1_TREE) ds.fn = disambiguate_tree_only; else if (flags & GET_SHA1_TREEISH) ds.fn = disambiguate_treeish_only; else if (flags & GET_SHA1_BLOB) ds.fn = disambiguate_blob_only; find_short_object_filename(len, hex_pfx, &ds); find_short_packed_object(len, bin_pfx, &ds); status = finish_object_disambiguation(&ds, sha1); if (!quietly && (status == SHORT_NAME_AMBIGUOUS)) return error("short SHA1 %.*s is ambiguous.", len, hex_pfx); return status; } int for_each_abbrev(const char *prefix, each_abbrev_fn fn, void *cb_data) { char hex_pfx[40]; unsigned char bin_pfx[20]; struct disambiguate_state ds; int len = strlen(prefix); if (len < MINIMUM_ABBREV || len > 40) return -1; if (prepare_prefixes(prefix, len, bin_pfx, hex_pfx) < 0) return -1; prepare_alt_odb(); memset(&ds, 0, sizeof(ds)); ds.always_call_fn = 1; ds.cb_data = cb_data; ds.fn = fn; find_short_object_filename(len, hex_pfx, &ds); find_short_packed_object(len, bin_pfx, &ds); return ds.ambiguous; } const char *find_unique_abbrev(const unsigned char *sha1, int len) { int status, exists; static char hex[41]; exists = has_sha1_file(sha1); memcpy(hex, sha1_to_hex(sha1), 40); if (len == 40 || !len) return hex; while (len < 40) { unsigned char sha1_ret[20]; status = get_short_sha1(hex, len, sha1_ret, GET_SHA1_QUIETLY); if (exists ? !status : status == SHORT_NAME_NOT_FOUND) { hex[len] = 0; return hex; } len++; } return hex; } static int ambiguous_path(const char *path, int len) { int slash = 1; int cnt; for (cnt = 0; cnt < len; cnt++) { switch (*path++) { case '\0': break; case '/': if (slash) break; slash = 1; continue; case '.': continue; default: slash = 0; continue; } break; } return slash; } static inline int upstream_mark(const char *string, int len) { const char *suffix[] = { "@{upstream}", "@{u}" }; int i; for (i = 0; i < ARRAY_SIZE(suffix); i++) { int suffix_len = strlen(suffix[i]); if (suffix_len <= len && !memcmp(string, suffix[i], suffix_len)) return suffix_len; } return 0; } static int get_sha1_1(const char *name, int len, unsigned char *sha1, unsigned lookup_flags); static int interpret_nth_prior_checkout(const char *name, struct strbuf *buf); static int get_sha1_basic(const char *str, int len, unsigned char *sha1) { static const char *warn_msg = "refname '%.*s' is ambiguous."; char *real_ref = NULL; int refs_found = 0; int at, reflog_len, nth_prior = 0; if (len == 40 && !get_sha1_hex(str, sha1)) return 0; /* basic@{time or number or -number} format to query ref-log */ reflog_len = at = 0; if (len && str[len-1] == '}') { for (at = len-4; at >= 0; at--) { if (str[at] == '@' && str[at+1] == '{') { if (str[at+2] == '-') { if (at != 0) /* @{-N} not at start */ return -1; nth_prior = 1; continue; } if (!upstream_mark(str + at, len - at)) { reflog_len = (len-1) - (at+2); len = at; } break; } } } /* Accept only unambiguous ref paths. */ if (len && ambiguous_path(str, len)) return -1; if (nth_prior) { struct strbuf buf = STRBUF_INIT; int detached; if (interpret_nth_prior_checkout(str, &buf) > 0) { detached = (buf.len == 40 && !get_sha1_hex(buf.buf, sha1)); strbuf_release(&buf); if (detached) return 0; } } if (!len && reflog_len) /* allow "@{...}" to mean the current branch reflog */ refs_found = dwim_ref("HEAD", 4, sha1, &real_ref); else if (reflog_len) refs_found = dwim_log(str, len, sha1, &real_ref); else refs_found = dwim_ref(str, len, sha1, &real_ref); if (!refs_found) return -1; if (warn_ambiguous_refs && refs_found > 1) warning(warn_msg, len, str); if (reflog_len) { int nth, i; unsigned long at_time; unsigned long co_time; int co_tz, co_cnt; /* Is it asking for N-th entry, or approxidate? */ for (i = nth = 0; 0 <= nth && i < reflog_len; i++) { char ch = str[at+2+i]; if ('0' <= ch && ch <= '9') nth = nth * 10 + ch - '0'; else nth = -1; } if (100000000 <= nth) { at_time = nth; nth = -1; } else if (0 <= nth) at_time = 0; else { int errors = 0; char *tmp = xstrndup(str + at + 2, reflog_len); at_time = approxidate_careful(tmp, &errors); free(tmp); if (errors) return -1; } if (read_ref_at(real_ref, at_time, nth, sha1, NULL, &co_time, &co_tz, &co_cnt)) { if (at_time) warning("Log for '%.*s' only goes " "back to %s.", len, str, show_date(co_time, co_tz, DATE_RFC2822)); else { free(real_ref); die("Log for '%.*s' only has %d entries.", len, str, co_cnt); } } } free(real_ref); return 0; } static int get_parent(const char *name, int len, unsigned char *result, int idx) { unsigned char sha1[20]; int ret = get_sha1_1(name, len, sha1, GET_SHA1_COMMITTISH); struct commit *commit; struct commit_list *p; if (ret) return ret; commit = lookup_commit_reference(sha1); if (!commit) return -1; if (parse_commit(commit)) return -1; if (!idx) { hashcpy(result, commit->object.sha1); return 0; } p = commit->parents; while (p) { if (!--idx) { hashcpy(result, p->item->object.sha1); return 0; } p = p->next; } return -1; } static int get_nth_ancestor(const char *name, int len, unsigned char *result, int generation) { unsigned char sha1[20]; struct commit *commit; int ret; ret = get_sha1_1(name, len, sha1, GET_SHA1_COMMITTISH); if (ret) return ret; commit = lookup_commit_reference(sha1); if (!commit) return -1; while (generation--) { if (parse_commit(commit) || !commit->parents) return -1; commit = commit->parents->item; } hashcpy(result, commit->object.sha1); return 0; } struct object *peel_to_type(const char *name, int namelen, struct object *o, enum object_type expected_type) { if (name && !namelen) namelen = strlen(name); while (1) { if (!o || (!o->parsed && !parse_object(o->sha1))) return NULL; if (expected_type == OBJ_ANY || o->type == expected_type) return o; if (o->type == OBJ_TAG) o = ((struct tag*) o)->tagged; else if (o->type == OBJ_COMMIT) o = &(((struct commit *) o)->tree->object); else { if (name) error("%.*s: expected %s type, but the object " "dereferences to %s type", namelen, name, typename(expected_type), typename(o->type)); return NULL; } } } static int peel_onion(const char *name, int len, unsigned char *sha1) { unsigned char outer[20]; const char *sp; unsigned int expected_type = 0; unsigned lookup_flags = 0; struct object *o; /* * "ref^{type}" dereferences ref repeatedly until you cannot * dereference anymore, or you get an object of given type, * whichever comes first. "ref^{}" means just dereference * tags until you get a non-tag. "ref^0" is a shorthand for * "ref^{commit}". "commit^{tree}" could be used to find the * top-level tree of the given commit. */ if (len < 4 || name[len-1] != '}') return -1; for (sp = name + len - 1; name <= sp; sp--) { int ch = *sp; if (ch == '{' && name < sp && sp[-1] == '^') break; } if (sp <= name) return -1; sp++; /* beginning of type name, or closing brace for empty */ if (!strncmp(commit_type, sp, 6) && sp[6] == '}') expected_type = OBJ_COMMIT; else if (!strncmp(tree_type, sp, 4) && sp[4] == '}') expected_type = OBJ_TREE; else if (!strncmp(blob_type, sp, 4) && sp[4] == '}') expected_type = OBJ_BLOB; else if (!prefixcmp(sp, "object}")) expected_type = OBJ_ANY; else if (sp[0] == '}') expected_type = OBJ_NONE; else if (sp[0] == '/') expected_type = OBJ_COMMIT; else return -1; if (expected_type == OBJ_COMMIT) lookup_flags = GET_SHA1_COMMITTISH; else if (expected_type == OBJ_TREE) lookup_flags = GET_SHA1_TREEISH; if (get_sha1_1(name, sp - name - 2, outer, lookup_flags)) return -1; o = parse_object(outer); if (!o) return -1; if (!expected_type) { o = deref_tag(o, name, sp - name - 2); if (!o || (!o->parsed && !parse_object(o->sha1))) return -1; hashcpy(sha1, o->sha1); return 0; } /* * At this point, the syntax look correct, so * if we do not get the needed object, we should * barf. */ o = peel_to_type(name, len, o, expected_type); if (!o) return -1; hashcpy(sha1, o->sha1); if (sp[0] == '/') { /* "$commit^{/foo}" */ char *prefix; int ret; struct commit_list *list = NULL; /* * $commit^{/}. Some regex implementation may reject. * We don't need regex anyway. '' pattern always matches. */ if (sp[1] == '}') return 0; prefix = xstrndup(sp + 1, name + len - 1 - (sp + 1)); commit_list_insert((struct commit *)o, &list); ret = get_sha1_oneline(prefix, sha1, list); free(prefix); return ret; } return 0; } static int get_describe_name(const char *name, int len, unsigned char *sha1) { const char *cp; unsigned flags = GET_SHA1_QUIETLY | GET_SHA1_COMMIT; for (cp = name + len - 1; name + 2 <= cp; cp--) { char ch = *cp; if (hexval(ch) & ~0377) { /* We must be looking at g in "SOMETHING-g" * for it to be describe output. */ if (ch == 'g' && cp[-1] == '-') { cp++; len -= cp - name; return get_short_sha1(cp, len, sha1, flags); } } } return -1; } static int get_sha1_1(const char *name, int len, unsigned char *sha1, unsigned lookup_flags) { int ret, has_suffix; const char *cp; /* * "name~3" is "name^^^", "name~" is "name~1", and "name^" is "name^1". */ has_suffix = 0; for (cp = name + len - 1; name <= cp; cp--) { int ch = *cp; if ('0' <= ch && ch <= '9') continue; if (ch == '~' || ch == '^') has_suffix = ch; break; } if (has_suffix) { int num = 0; int len1 = cp - name; cp++; while (cp < name + len) num = num * 10 + *cp++ - '0'; if (!num && len1 == len - 1) num = 1; if (has_suffix == '^') return get_parent(name, len1, sha1, num); /* else if (has_suffix == '~') -- goes without saying */ return get_nth_ancestor(name, len1, sha1, num); } ret = peel_onion(name, len, sha1); if (!ret) return 0; ret = get_sha1_basic(name, len, sha1); if (!ret) return 0; /* It could be describe output that is "SOMETHING-gXXXX" */ ret = get_describe_name(name, len, sha1); if (!ret) return 0; return get_short_sha1(name, len, sha1, lookup_flags); } /* * This interprets names like ':/Initial revision of "git"' by searching * through history and returning the first commit whose message starts * the given regular expression. * * For future extension, ':/!' is reserved. If you want to match a message * beginning with a '!', you have to repeat the exclamation mark. */ #define ONELINE_SEEN (1u<<20) static int handle_one_ref(const char *path, const unsigned char *sha1, int flag, void *cb_data) { struct commit_list **list = cb_data; struct object *object = parse_object(sha1); if (!object) return 0; if (object->type == OBJ_TAG) { object = deref_tag(object, path, strlen(path)); if (!object) return 0; } if (object->type != OBJ_COMMIT) return 0; commit_list_insert_by_date((struct commit *)object, list); return 0; } static int get_sha1_oneline(const char *prefix, unsigned char *sha1, struct commit_list *list) { struct commit_list *backup = NULL, *l; int found = 0; regex_t regex; if (prefix[0] == '!') { if (prefix[1] != '!') die ("Invalid search pattern: %s", prefix); prefix++; } if (regcomp(®ex, prefix, REG_EXTENDED)) die("Invalid search pattern: %s", prefix); for (l = list; l; l = l->next) { l->item->object.flags |= ONELINE_SEEN; commit_list_insert(l->item, &backup); } while (list) { char *p, *to_free = NULL; struct commit *commit; enum object_type type; unsigned long size; int matches; commit = pop_most_recent_commit(&list, ONELINE_SEEN); if (!parse_object(commit->object.sha1)) continue; if (commit->buffer) p = commit->buffer; else { p = read_sha1_file(commit->object.sha1, &type, &size); if (!p) continue; to_free = p; } p = strstr(p, "\n\n"); matches = p && !regexec(®ex, p + 2, 0, NULL, 0); free(to_free); if (matches) { hashcpy(sha1, commit->object.sha1); found = 1; break; } } regfree(®ex); free_commit_list(list); for (l = backup; l; l = l->next) clear_commit_marks(l->item, ONELINE_SEEN); free_commit_list(backup); return found ? 0 : -1; } struct grab_nth_branch_switch_cbdata { int remaining; struct strbuf buf; }; static int grab_nth_branch_switch(unsigned char *osha1, unsigned char *nsha1, const char *email, unsigned long timestamp, int tz, const char *message, void *cb_data) { struct grab_nth_branch_switch_cbdata *cb = cb_data; const char *match = NULL, *target = NULL; size_t len; if (!prefixcmp(message, "checkout: moving from ")) { match = message + strlen("checkout: moving from "); target = strstr(match, " to "); } if (!match || !target) return 0; if (--(cb->remaining) == 0) { len = target - match; strbuf_reset(&cb->buf); strbuf_add(&cb->buf, match, len); return 1; /* we are done */ } return 0; } /* * Parse @{-N} syntax, return the number of characters parsed * if successful; otherwise signal an error with negative value. */ static int interpret_nth_prior_checkout(const char *name, struct strbuf *buf) { long nth; int retval; struct grab_nth_branch_switch_cbdata cb; const char *brace; char *num_end; if (name[0] != '@' || name[1] != '{' || name[2] != '-') return -1; brace = strchr(name, '}'); if (!brace) return -1; nth = strtol(name + 3, &num_end, 10); if (num_end != brace) return -1; if (nth <= 0) return -1; cb.remaining = nth; strbuf_init(&cb.buf, 20); retval = 0; if (0 < for_each_reflog_ent_reverse("HEAD", grab_nth_branch_switch, &cb)) { strbuf_reset(buf); strbuf_add(buf, cb.buf.buf, cb.buf.len); retval = brace - name + 1; } strbuf_release(&cb.buf); return retval; } int get_sha1_mb(const char *name, unsigned char *sha1) { struct commit *one, *two; struct commit_list *mbs; unsigned char sha1_tmp[20]; const char *dots; int st; dots = strstr(name, "..."); if (!dots) return get_sha1(name, sha1); if (dots == name) st = get_sha1("HEAD", sha1_tmp); else { struct strbuf sb; strbuf_init(&sb, dots - name); strbuf_add(&sb, name, dots - name); st = get_sha1_committish(sb.buf, sha1_tmp); strbuf_release(&sb); } if (st) return st; one = lookup_commit_reference_gently(sha1_tmp, 0); if (!one) return -1; if (get_sha1_committish(dots[3] ? (dots + 3) : "HEAD", sha1_tmp)) return -1; two = lookup_commit_reference_gently(sha1_tmp, 0); if (!two) return -1; mbs = get_merge_bases(one, two, 1); if (!mbs || mbs->next) st = -1; else { st = 0; hashcpy(sha1, mbs->item->object.sha1); } free_commit_list(mbs); return st; } /* parse @something syntax, when 'something' is not {.*} */ static int interpret_empty_at(const char *name, int namelen, int len, struct strbuf *buf) { if (len || name[1] == '{') return -1; strbuf_reset(buf); strbuf_add(buf, "HEAD", 4); return 1; } static int reinterpret(const char *name, int namelen, int len, struct strbuf *buf) { /* we have extra data, which might need further processing */ struct strbuf tmp = STRBUF_INIT; int used = buf->len; int ret; strbuf_add(buf, name + len, namelen - len); ret = interpret_branch_name(buf->buf, &tmp); /* that data was not interpreted, remove our cruft */ if (ret < 0) { strbuf_setlen(buf, used); return len; } strbuf_reset(buf); strbuf_addbuf(buf, &tmp); strbuf_release(&tmp); /* tweak for size of {-N} versus expanded ref name */ return ret - used + len; } /* * This reads short-hand syntax that not only evaluates to a commit * object name, but also can act as if the end user spelled the name * of the branch from the command line. * * - "@{-N}" finds the name of the Nth previous branch we were on, and * places the name of the branch in the given buf and returns the * number of characters parsed if successful. * * - "@{upstream}" finds the name of the other ref that * is configured to merge with (missing defaults * to the current branch), and places the name of the branch in the * given buf and returns the number of characters parsed if * successful. * * If the input is not of the accepted format, it returns a negative * number to signal an error. * * If the input was ok but there are not N branch switches in the * reflog, it returns 0. */ int interpret_branch_name(const char *name, struct strbuf *buf) { char *cp; struct branch *upstream; int namelen = strlen(name); int len = interpret_nth_prior_checkout(name, buf); int tmp_len; if (!len) { return len; /* syntax Ok, not enough switches */ } else if (len > 0) { if (len == namelen) return len; /* consumed all */ else return reinterpret(name, namelen, len, buf); } cp = strchr(name, '@'); if (!cp) return -1; len = interpret_empty_at(name, namelen, cp - name, buf); if (len > 0) return reinterpret(name, namelen, len, buf); tmp_len = upstream_mark(cp, namelen - (cp - name)); if (!tmp_len) return -1; len = cp + tmp_len - name; cp = xstrndup(name, cp - name); upstream = branch_get(*cp ? cp : NULL); /* * Upstream can be NULL only if cp refers to HEAD and HEAD * points to something different than a branch. */ if (!upstream) return error(_("HEAD does not point to a branch")); if (!upstream->merge || !upstream->merge[0]->dst) { if (!ref_exists(upstream->refname)) return error(_("No such branch: '%s'"), cp); if (!upstream->merge) return error(_("No upstream configured for branch '%s'"), upstream->name); return error( _("Upstream branch '%s' not stored as a remote-tracking branch"), upstream->merge[0]->src); } free(cp); cp = shorten_unambiguous_ref(upstream->merge[0]->dst, 0); strbuf_reset(buf); strbuf_addstr(buf, cp); free(cp); return len; } int strbuf_branchname(struct strbuf *sb, const char *name) { int len = strlen(name); if (interpret_branch_name(name, sb) == len) return 0; strbuf_add(sb, name, len); return len; } int strbuf_check_branch_ref(struct strbuf *sb, const char *name) { strbuf_branchname(sb, name); if (name[0] == '-') return -1; strbuf_splice(sb, 0, 0, "refs/heads/", 11); return check_refname_format(sb->buf, 0); } /* * This is like "get_sha1_basic()", except it allows "sha1 expressions", * notably "xyz^" for "parent of xyz" */ int get_sha1(const char *name, unsigned char *sha1) { struct object_context unused; return get_sha1_with_context(name, 0, sha1, &unused); } /* * Many callers know that the user meant to name a committish by * syntactical positions where the object name appears. Calling this * function allows the machinery to disambiguate shorter-than-unique * abbreviated object names between committish and others. * * Note that this does NOT error out when the named object is not a * committish. It is merely to give a hint to the disambiguation * machinery. */ int get_sha1_committish(const char *name, unsigned char *sha1) { struct object_context unused; return get_sha1_with_context(name, GET_SHA1_COMMITTISH, sha1, &unused); } int get_sha1_treeish(const char *name, unsigned char *sha1) { struct object_context unused; return get_sha1_with_context(name, GET_SHA1_TREEISH, sha1, &unused); } int get_sha1_commit(const char *name, unsigned char *sha1) { struct object_context unused; return get_sha1_with_context(name, GET_SHA1_COMMIT, sha1, &unused); } int get_sha1_tree(const char *name, unsigned char *sha1) { struct object_context unused; return get_sha1_with_context(name, GET_SHA1_TREE, sha1, &unused); } int get_sha1_blob(const char *name, unsigned char *sha1) { struct object_context unused; return get_sha1_with_context(name, GET_SHA1_BLOB, sha1, &unused); } /* Must be called only when object_name:filename doesn't exist. */ static void diagnose_invalid_sha1_path(const char *prefix, const char *filename, const unsigned char *tree_sha1, const char *object_name, int object_name_len) { struct stat st; unsigned char sha1[20]; unsigned mode; if (!prefix) prefix = ""; if (!lstat(filename, &st)) die("Path '%s' exists on disk, but not in '%.*s'.", filename, object_name_len, object_name); if (errno == ENOENT || errno == ENOTDIR) { char *fullname = xmalloc(strlen(filename) + strlen(prefix) + 1); strcpy(fullname, prefix); strcat(fullname, filename); if (!get_tree_entry(tree_sha1, fullname, sha1, &mode)) { die("Path '%s' exists, but not '%s'.\n" "Did you mean '%.*s:%s' aka '%.*s:./%s'?", fullname, filename, object_name_len, object_name, fullname, object_name_len, object_name, filename); } die("Path '%s' does not exist in '%.*s'", filename, object_name_len, object_name); } } /* Must be called only when :stage:filename doesn't exist. */ static void diagnose_invalid_index_path(int stage, const char *prefix, const char *filename) { struct stat st; struct cache_entry *ce; int pos; unsigned namelen = strlen(filename); unsigned fullnamelen; char *fullname; if (!prefix) prefix = ""; /* Wrong stage number? */ pos = cache_name_pos(filename, namelen); if (pos < 0) pos = -pos - 1; if (pos < active_nr) { ce = active_cache[pos]; if (ce_namelen(ce) == namelen && !memcmp(ce->name, filename, namelen)) die("Path '%s' is in the index, but not at stage %d.\n" "Did you mean ':%d:%s'?", filename, stage, ce_stage(ce), filename); } /* Confusion between relative and absolute filenames? */ fullnamelen = namelen + strlen(prefix); fullname = xmalloc(fullnamelen + 1); strcpy(fullname, prefix); strcat(fullname, filename); pos = cache_name_pos(fullname, fullnamelen); if (pos < 0) pos = -pos - 1; if (pos < active_nr) { ce = active_cache[pos]; if (ce_namelen(ce) == fullnamelen && !memcmp(ce->name, fullname, fullnamelen)) die("Path '%s' is in the index, but not '%s'.\n" "Did you mean ':%d:%s' aka ':%d:./%s'?", fullname, filename, ce_stage(ce), fullname, ce_stage(ce), filename); } if (!lstat(filename, &st)) die("Path '%s' exists on disk, but not in the index.", filename); if (errno == ENOENT || errno == ENOTDIR) die("Path '%s' does not exist (neither on disk nor in the index).", filename); free(fullname); } static char *resolve_relative_path(const char *rel) { if (prefixcmp(rel, "./") && prefixcmp(rel, "../")) return NULL; if (!startup_info) die("BUG: startup_info struct is not initialized."); if (!is_inside_work_tree()) die("relative path syntax can't be used outside working tree."); /* die() inside prefix_path() if resolved path is outside worktree */ return prefix_path(startup_info->prefix, startup_info->prefix ? strlen(startup_info->prefix) : 0, rel); } static int get_sha1_with_context_1(const char *name, unsigned flags, const char *prefix, unsigned char *sha1, struct object_context *oc) { int ret, bracket_depth; int namelen = strlen(name); const char *cp; int only_to_die = flags & GET_SHA1_ONLY_TO_DIE; memset(oc, 0, sizeof(*oc)); oc->mode = S_IFINVALID; ret = get_sha1_1(name, namelen, sha1, flags); if (!ret) return ret; /* * sha1:path --> object name of path in ent sha1 * :path -> object name of absolute path in index * :./path -> object name of path relative to cwd in index * :[0-3]:path -> object name of path in index at stage * :/foo -> recent commit matching foo */ if (name[0] == ':') { int stage = 0; struct cache_entry *ce; char *new_path = NULL; int pos; if (!only_to_die && namelen > 2 && name[1] == '/') { struct commit_list *list = NULL; for_each_ref(handle_one_ref, &list); return get_sha1_oneline(name + 2, sha1, list); } if (namelen < 3 || name[2] != ':' || name[1] < '0' || '3' < name[1]) cp = name + 1; else { stage = name[1] - '0'; cp = name + 3; } new_path = resolve_relative_path(cp); if (!new_path) { namelen = namelen - (cp - name); } else { cp = new_path; namelen = strlen(cp); } strncpy(oc->path, cp, sizeof(oc->path)); oc->path[sizeof(oc->path)-1] = '\0'; if (!active_cache) read_cache(); pos = cache_name_pos(cp, namelen); if (pos < 0) pos = -pos - 1; while (pos < active_nr) { ce = active_cache[pos]; if (ce_namelen(ce) != namelen || memcmp(ce->name, cp, namelen)) break; if (ce_stage(ce) == stage) { hashcpy(sha1, ce->sha1); oc->mode = ce->ce_mode; free(new_path); return 0; } pos++; } if (only_to_die && name[1] && name[1] != '/') diagnose_invalid_index_path(stage, prefix, cp); free(new_path); return -1; } for (cp = name, bracket_depth = 0; *cp; cp++) { if (*cp == '{') bracket_depth++; else if (bracket_depth && *cp == '}') bracket_depth--; else if (!bracket_depth && *cp == ':') break; } if (*cp == ':') { unsigned char tree_sha1[20]; int len = cp - name; if (!get_sha1_1(name, len, tree_sha1, GET_SHA1_TREEISH)) { const char *filename = cp+1; char *new_filename = NULL; new_filename = resolve_relative_path(filename); if (new_filename) filename = new_filename; ret = get_tree_entry(tree_sha1, filename, sha1, &oc->mode); if (ret && only_to_die) { diagnose_invalid_sha1_path(prefix, filename, tree_sha1, name, len); } hashcpy(oc->tree, tree_sha1); strncpy(oc->path, filename, sizeof(oc->path)); oc->path[sizeof(oc->path)-1] = '\0'; free(new_filename); return ret; } else { if (only_to_die) die("Invalid object name '%.*s'.", len, name); } } return ret; } /* * Call this function when you know "name" given by the end user must * name an object but it doesn't; the function _may_ die with a better * diagnostic message than "no such object 'name'", e.g. "Path 'doc' does not * exist in 'HEAD'" when given "HEAD:doc", or it may return in which case * you have a chance to diagnose the error further. */ void maybe_die_on_misspelt_object_name(const char *name, const char *prefix) { struct object_context oc; unsigned char sha1[20]; get_sha1_with_context_1(name, GET_SHA1_ONLY_TO_DIE, prefix, sha1, &oc); } int get_sha1_with_context(const char *str, unsigned flags, unsigned char *sha1, struct object_context *orc) { return get_sha1_with_context_1(str, flags, NULL, sha1, orc); }